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Linear and Nonlinear Optical Properties of Single GaAs Nanowires With Polytypism Ana Clara Sampaio Pimenta, Danielle Cristina Teles Ferreira, Daniel Bretas Roa, Marcus V.B. Moreira, Alfredo Gontijo de Oliveira, Juan C Gonzalez, Milena De Giorgi, Daniele Sanvitto, and Franklin Massami Matinaga J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.6b04458 • Publication Date (Web): 01 Jul 2016 Downloaded from http://pubs.acs.org on July 5, 2016
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The Journal of Physical Chemistry
Linear and Nonlinear Optical Properties of Single GaAs Nanowires with Polytypism
A. C. S. Pimenta1, D. C. T. Ferreira1, D. B. Roa2, M. V. B. Moreira2, A. G. de Oliveira2, J. C. González2, M. de Giorgi3, D. Sanvitto3, F. M. Matinaga1* 1
Photonic Lab., Dep. de Física, Av. Antônio Carlos 6627, Pampulha, Belo Horizonte, Brazil.
2
Molecular Beam Epitaxy lab., Dep.de Física, Av. Antônio Carlos 6627, Pampulha, Belo Horizonte, Brazil.
3
Nanotec - Istituto Nanotecnologia - CNR, via Monteroni 73100, Lecce, Italy.
Abstract: We report the linear and nonlinear optical properties of single GaAs nanowires with polytypism effect. Electron transmission microscopy experiments shows that the nanowires contain wurtzite segments as well as zinc blende segments with two different crystallographic orientations. Time resolved photoluminescence spectroscopy of single nanowires shows ultrafast radiative recombination lifetimes in the range of 20 ps - 70 ps as consequence of the charge scattering in the type-II band alignment between WZ and ZB segments and or by the high surface area of the nanowires. Polarization resolved second harmonic generation in the nanowires found to be highly sensitive to the crystallography of the nanowires. All three crystal axes orientations of the nanowires were determined. Furthermore, the volume fraction of the ZB segments oriented in the [0-11] and in the [01-1] directions was precisely determined for the first time by optical measurement besides the TEM technique.
Introduction: Polytypism is commonly observed as coexisting segments of zinc blende (ZB) and wurtzide (WZ) phases in III-V nanowires (NWs), although typically only the ZB phase is observed in bulk GaAs epitaxial layers.1,2 The ZB-WZ polytypism has shown to strongly modify the electronic and optical properties of III-V NWs.3-5 Although a lot of effort has been dedicated to study the linear69
and nonlinear10-11 optical properties of III-V NWs, the photoluminescence (PL) dynamics need
additional clarifications. At room temperature, the carrier recombination is governed by nonradiative decay process,12 which indicate a direct consequence of the high surface/volume 1 ACS Paragon Plus Environment
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relationship in these NWs. Such a fast decay comes in opposition to the quantum well wires (QWR) decay time on the order of 310 ps.13,14 These issues have motivated many groups to work on the engineering of the WZ and ZB phases and on the control of nonradiative process on the surface of the NWs, as in the work in core-shell passivated NWs.12,15 Theses linear and nonlinear optical properties are deterministic factors for the application of semiconductor NWs in optoelectronics.16,17 In addition to the polytypic segments, ZB segments can also rotate around the growth axis of the NWs creating two different ZB plates that are well characterized by TEM measurements, however such twining is not yet observed in linear and nonlinear optical process broadly applied to study single semiconductor NWs (SNW) over the last decade.10,11,18,19 Besides the application on higher energy coherent light generation, SHG have the advantage of optically test structural properties of single nanostructures, like it´s crystallographic orientation,11,19 due to the high sensitivity to the excitation intensity as well as to the emission light polarization angle properties of the SNWs. GaAs ZB structure with 4�3m symmetry is one of the highest possible asymmetric semiconductor crystals with the nonlinear d14 susceptibility coefficient (d14=8x10-22MKS).20 On the last decade, GaAs NW have been studied by experimental11,18,19,21,22 as well as by the theory10 groups, however there is still many controversial results around nonlinear coefficient dependence with the band structures10,23 as well as the linear optical crystal energy gap4,5 and also on the energy relation between the ZB and WZ phases presented in SNWs.7 In this work we show experimental results for time resolved photoluminescence (TRPL) and SHG for GaAs single nanowires grown by molecular beam epitaxy (MBE), containing ZB and WZ phases. Very fast PL excitonic decay time (20 ps to 70 ps) followed by a slow (~250 ps) PL decay were observed. Such results for our knowledge, is almost an order smaller than the reported results at 4K. The SHG blue (~415 nm) emission dependence with the excitation polarization angle in relation to the crystal axis “c”, show clearly the crystallography of SNW by identifying the presence of WZ phase and ZB phase segments with two distinct crystallographic orientations. These results are in excellent agreement with high resolution transmission electron measurements (HRTEM) of the SNWs, and this correlation of the SHG with ZB orientation twinning never has been reported.
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Experimental Section: Free standing GaAs NWs were grown by the Au assisted vapor-liquid-solid (VLS) mechanism on Si (111) substrates by MBE in a Riber 2300 R&D system. The growth was performed at 500 °C during 90 min, with an As4 BEP of 3.4×10-5 Torr, a Ga BEP of 7.2×10-7 Torr and at a nominal growth rate of 1 µm/h. Prior to the deposition, a fraction of the surface of the substrate was drop coated with Au colloidal nanoparticles (average diameter of (5 ± 1) nm) which promoted the growth of NWs of around tenths of nm thick and several micrometers in lengths as described somewhere.25 To study a SNW, the grown sample was mechanically wiped onto a clean Si flat substrate to facilitate optical characterization. The crystalline structure of the NWs was investigated by transmission electron microscopy (TEM) by using a Tecnai G2-20 SuperTwin FEI high resolution electron microscope. Figure 1(a) shows a TEM image of a 40 nm thick GaAs NW. A high resolution TEM (HRTEM) image and corresponding selected area electron diffraction (SAED) pattern of the NW are shown in Figure 1(b) and 1(c), respectively. This diffraction pattern is actually a composition of three different patterns corresponding to ZB segments with zone axes [0-11], WZ segments with zone axis [1-210] and ZB segments with zone axis [01-1]. Therefore, not only alternated ZB/WZ regions exist in the GaAs NWs, but there is also ZB segments rotated with respect to each other. By correlating the SAED patterns of Figure 1(c) with the Fast Fourier Transform (FFT) of the region of interest in the HRTEM image (inserts of Figure 1(b)) it is possible to identify the structure and orientation of any segment along the NW. A silicon substrate with several transferred GaAs NWs was mounted in a closed He gas flow cryostat and cooled down to 4 K. PL experiments were performed by using a microphotoluminescence (µ-PL) setup coupled to a Jobin Yvon spectrometer (IHR-320) with a Hamamatsu EM-CCD. A 100 X objective lens were used to focus/collect the laser/emitted light.
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Figure 1. (a) TEM image of a GaAs NW. (b) HRTEM image of the NW. (c) SAED pattern. The sample was non-resonantly excited by a 100 fs Ti:Sapphire laser tuned at 720 nm. In order to measure the temporal dynamic of a selected spectrum, the laser was synchronized with a Si avalanche photodiode (APD) (Figure 2) coupled on the output of the same spectrometer with a time resolution of 23 ps limited by system response. For the SHG experiments, a similar µ-PL setup was used. A pulsed Ti:Sapphire laser (FWHM = 50 fs) at 830nm was defocused to a spot larger than 5 µm, in order to avoid SNW heating, with a 20X– 0.4 NA objective lens. The back-scattered laser light from the SNW was filtered and the violet (415nm) SHG emission was collected by the same objective lens and dispersed with the 300 l/mm grating of a spectrometer equipped with a liquid nitrogen cooled silicon charge coupled detector (CCD). The SNW was kept at room temperature, always remaining in a horizontal plane.
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Figure 2 a) Optical spectroscopy setup used for TRPL and SHG experiments with the sample (S), objective lens (O), beam splitter (B.S.), lens (L), filter (F), prism polarizer (P), half wave plate (λ/2), attenuator (A), mirrors(M), Ti:Saphire laser (L-T), cryostat (C), computer (PC), avalanche photodiode (APD) and spectrometer (Spec.) with components (CCD). b) NW grows (“c”) orientation aligned to “x” coordinate, used as reference to the laser excitation angle.
Results & Discussion: Figure 3(a) shows the measured PL spectra at 4K. We measured three different positions (a: left, b: medium and c: right) of SNW 1, with energy peaks from 1.48 eV to 1.52 eV (see values also SNW 2 position a:left and b:right in table 1). Some peak energy values are below the ZB energy gap (EgZB) and WZ energy gap (EgWZ), in agreement with the reported type II band alignement4,5,7 between the ZB and WZ segments in the NWs. The periodic oscillations observed in the PL peaks are artifacts due to the Etalon effect, which is a characteristic issue of backilluminated CCD camera.26 Figure 3(b) shows the time decay curve measured at the PL energy peak of the SNW 1, as well as the pulse response curve of the laser. All SNW PL decay curves show a double exponential decay which can be fitted by using the equation:
Figure 3. a) PL spectra taken at three different positions (a, b and c) of SNW 1. b) TRPL decay curves acquired at the PL peak energy and positions a, b and c of SNW 1. The laser pulse response curve is also shown for comparison purposes.
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-t -t I�� �t� = A × exp� �τ� � + B × exp � �τ� �
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(1)
where A and B are constants and τ1,2 are the characteristics PL decay times. Table 1 summarizes the values of τ1, τ2 obtained by fitting eq. (1) to the TRPL decay curve of the NWs after a deconvolution with the laser response curve and the peak energy (Ep) and full width at half maximum (FWHM) of the PL emission for each position of both NWs. Those results represent a recombination decay time and the PL peak energy for two GaAs SNWs, showing the PL emitted by a NW piece smaller than a micron of length (spot size of the laser across the objective lens). The very fast luminescence decay (τ1 = 21 – 73 ps) followed by the usual longer time decay (τ2>200 ps), this second longer decay behavior are observed in mesa stripe type nanowires,13 and in core-shell type GaAs nanowires.15 In our NWs, characterized by a ZB / WZ phase polytypism, the existence of regions with µ-PL peak energy smaller than ZB / WZ energy gap (EZB/EWZ) along the NWs (see Table 1) comes in agreement with the recombination process presented in type II band alignment4,5,7 as illustrated in Figure 4. Table 1: PL and TRPL data for two single GaAs NW. SNW 1
SNW 2
Position
a
b
c
a
b
τ1 (ps)
27
36
21
73
46
τ2 (ps)
280
205
256
298
329
Ep (eV)
1.51
1.48
1.48
1.52
1.51
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FWHM (meV)
16
39
53
16
17
The excited carriers in such band alignment spread very quickly in many channels (Figure 4, route (c) by ballistic transfer (< 0.1 ps)13 and the trapped carrier along the channels explain the PL spectrum in the range of 1.48–1.52 eV (transitions (a) and (b) in Figure 4). This carrier spreading can be understood mainly in terms of absorption of the excitation light by the ZB segments and a ultrafast scattering of those charge carrier along the wire, i.e. there is not a single, but many possible decay channels, resulting in a quasi-continuum energy line broadening (16 to 53 meV) for the excited energy band due to the width differences between WZ and ZB segments along the NW.6 Such exciton spreading with acoustic phonons is much more efficient in these crystal-phase disks than in structures like (Al,Ga)As/GaAs quantum wells.6 On the other side, the fast exciton scattering determines the exciton coherence volume, which acts directly on the exciton recombination time,6,27 moreover, the multiple segments act like multiple quantum well structures, enhancing the exciton longitudinaltransversal splitting.28 Such dynamic would result in an ultrafast radiative recombination time (τr) in the range of 21 ps -73 ps observed for our GaAs single NWs.
Figure 4. Band alignment model for a WZ / ZB polytypic GaAs NW, showing the direct (a) and indirect (b) transitions, as well as the carrier scattering routes (c) that generate different recombination channels. In spite of rough comparative data of different structural and growing process, our measured values are almost an order smaller than the excitonic recombination time observed on 7 ACS Paragon Plus Environment
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GaAs QWR studied previously7,13 as well as quantum well structures.27 Furthermore, the lowest activation energy for nonradiative recombination channels in our NWs is 1.1 meV,25 which would be activated at temperature above 13.5 K, so the present PL results would come mainly from radiative recombination decay process. Therefore, we conclude that the differences in peak energy and recombination time are a result of the polytypic distributions of the WZ and ZB phases at each corresponding measured region of the SNW. Figure 5a) shows the SHG spectrum of a SNW, with a Gaussian shape and a bandwidth of ∆FWHM ~ 5 nm smaller than the excitation pulse laser ∆FWHM ~ 12 nm at 815 nm. Figure 5b) shows the intensity of the SHG spectrum as a function of the power of the excitation laser. A slope of ~ 2 was obtained for low pump power, while a saturation of the curve due to sample heating can be observed at high pump power. The SHG integrated spectrum data as a function of the pump light polarization angle θ (see Figure 2) is shown in Figure 6. A Glan Thonpson prism polarizer in the entrance path of the spectrometer guarantee that we measured only the SHG polarization emission component parallel to the SNW growth “c” axis (Figure 6a) and after rotating the prism, the perpendicular “y” axis component were measured (Figure 6c). Since a large laser spot size was used, the measured SHG intensity comes from a large quantity of both ZB and WZ segments along the SNW. The total SHG emission can be considered as a sum of all contributions from WZ and ZB segments. However, the ZB segments present contributions from two segments with rotated axis observed in the TEM images. Therefore, the emission polarized parallel to the “c” axis of the SNW for the WZ segments is proportional to:19
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Figure 5a) The SHG light spectra generated by a SNW and b) the nonlinear SHG intensity & laser power relation, the linear solid line represent the data fitting with a slope close to 2 at low pump power. ��� �
��� �
�� ����,� ∝ � � × !"#$�%�& × '(( + $)*�%�& × '(� + ���
(2)
���
where IL is the laser intensity and '(( and '(� are second order nonlinear elements of the 6mm WZ optical susceptibility tensor. The emission polarized parallel to the “c” axis of the SNW for the ZB segments is proportional to: 16,18 ��� �
�, ∝ � � × '�& × ["#$�%�� − 0.5 × sin �%�� ]� ����,�
(3)
���
where χ�& is the second order nonlinear elements of ZB optical susceptibility tensor. The perpendicular emission, parallel to the “y” axis, for the WZ segments is proportional to:21 ��� �
�� ����,7 ∝ � � × '�8 × $)*�%�� × cos�%��
(4)
���
where '�8 is a second order nonlinear elements of the 6mm WZ optical susceptibility tensor. The perpendicular emission, parallel to the “y” axis, for the ZB segments is proportional to: 16,18 ��� �
�, ����,7 ∝ � � × '�& × ;< × [sin�%� × cos�%� − =� × sin �%�� ]� + �1 −
